Xiaolin Liu, Hao Yang, Hassan Harb, Rajarshi Samajdar, Toby J. Woods, Oliver Lin, Qian Chen, Adolfo I. B. Romo, Joaquín Rodríguez-López, Rajeev S. Assary, Jeffrey S. Moore, Charles M. Schroeder
{"title":"形状持久的梯形分子在单分子结中表现出与纳米间隙无关的传导性。","authors":"Xiaolin Liu, Hao Yang, Hassan Harb, Rajarshi Samajdar, Toby J. Woods, Oliver Lin, Qian Chen, Adolfo I. B. Romo, Joaquín Rodríguez-López, Rajeev S. Assary, Jeffrey S. Moore, Charles M. Schroeder","doi":"10.1038/s41557-024-01619-5","DOIUrl":null,"url":null,"abstract":"Molecular electronic devices require precise control over the flow of current in single molecules. However, the electron transport properties of single molecules critically depend on dynamic molecular conformations in nanoscale junctions. Here we report a unique strategy for controlling molecular conductance using shape-persistent molecules. Chemically diverse, charged ladder molecules, synthesized via a one-pot multicomponent ladderization strategy, show a molecular conductance (d[log(G/G0)]/dx ≈ −0.1 nm−1) that is nearly independent of junction displacement, in stark contrast to the nanogap-dependent conductance (d[log(G/G0)]/dx ≈ −7 nm−1) observed for non-ladder analogues. Ladder molecules show an unusually narrow distribution of molecular conductance during dynamic junction displacement, which is attributed to the shape-persistent backbone and restricted rotation of terminal anchor groups. These principles are further extended to a butterfly-like molecule, thereby demonstrating the strategy’s generality for achieving gap-independent conductance. Overall, our work provides important avenues for controlling molecular conductance using shape-persistent molecules. Achieving robust and controllable conductance in single-molecule junctions is challenging due to the dynamic nature of molecular conformations that fluctuate over operational timescales. A strategy using shape-persistent molecules has now been developed that demonstrates nearly junction-displacement-independent conductance, providing a stable solution for single-molecule electronic properties.","PeriodicalId":18909,"journal":{"name":"Nature chemistry","volume":"16 11","pages":"1772-1780"},"PeriodicalIF":19.2000,"publicationDate":"2024-08-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Shape-persistent ladder molecules exhibit nanogap-independent conductance in single-molecule junctions\",\"authors\":\"Xiaolin Liu, Hao Yang, Hassan Harb, Rajarshi Samajdar, Toby J. Woods, Oliver Lin, Qian Chen, Adolfo I. B. Romo, Joaquín Rodríguez-López, Rajeev S. Assary, Jeffrey S. Moore, Charles M. Schroeder\",\"doi\":\"10.1038/s41557-024-01619-5\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Molecular electronic devices require precise control over the flow of current in single molecules. However, the electron transport properties of single molecules critically depend on dynamic molecular conformations in nanoscale junctions. Here we report a unique strategy for controlling molecular conductance using shape-persistent molecules. Chemically diverse, charged ladder molecules, synthesized via a one-pot multicomponent ladderization strategy, show a molecular conductance (d[log(G/G0)]/dx ≈ −0.1 nm−1) that is nearly independent of junction displacement, in stark contrast to the nanogap-dependent conductance (d[log(G/G0)]/dx ≈ −7 nm−1) observed for non-ladder analogues. Ladder molecules show an unusually narrow distribution of molecular conductance during dynamic junction displacement, which is attributed to the shape-persistent backbone and restricted rotation of terminal anchor groups. These principles are further extended to a butterfly-like molecule, thereby demonstrating the strategy’s generality for achieving gap-independent conductance. Overall, our work provides important avenues for controlling molecular conductance using shape-persistent molecules. Achieving robust and controllable conductance in single-molecule junctions is challenging due to the dynamic nature of molecular conformations that fluctuate over operational timescales. 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Shape-persistent ladder molecules exhibit nanogap-independent conductance in single-molecule junctions
Molecular electronic devices require precise control over the flow of current in single molecules. However, the electron transport properties of single molecules critically depend on dynamic molecular conformations in nanoscale junctions. Here we report a unique strategy for controlling molecular conductance using shape-persistent molecules. Chemically diverse, charged ladder molecules, synthesized via a one-pot multicomponent ladderization strategy, show a molecular conductance (d[log(G/G0)]/dx ≈ −0.1 nm−1) that is nearly independent of junction displacement, in stark contrast to the nanogap-dependent conductance (d[log(G/G0)]/dx ≈ −7 nm−1) observed for non-ladder analogues. Ladder molecules show an unusually narrow distribution of molecular conductance during dynamic junction displacement, which is attributed to the shape-persistent backbone and restricted rotation of terminal anchor groups. These principles are further extended to a butterfly-like molecule, thereby demonstrating the strategy’s generality for achieving gap-independent conductance. Overall, our work provides important avenues for controlling molecular conductance using shape-persistent molecules. Achieving robust and controllable conductance in single-molecule junctions is challenging due to the dynamic nature of molecular conformations that fluctuate over operational timescales. A strategy using shape-persistent molecules has now been developed that demonstrates nearly junction-displacement-independent conductance, providing a stable solution for single-molecule electronic properties.
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